~ 1~250~ P-10873 A METHOD OF SURFACE TREATMENT OF TIN
PLATED CANS AND TIN PLATED STEEL SHEETS
BACKGRO~ND OF THE INVENTION
This invention is concerned with a method for the surface treatment of tin plated steel sheet (referred to below as tin plate) and drawn and ironed cans of tin plated steel sheet (referred to below as tin cans). It is an object to form a coating on the tin surface whlch is corroslon resistant and oxidation resistant and exhibits good paintability either chemically or electrolytically.
In the past aqueous solutions of phosphoric acid and chromic acid or chromic acid salts in aqueous solution have been used as surface treatment baths for tin surfaces.
Surface treatment methods based on chromic acid salts of this sort are excellent surface treatment methods for tin but there is a disadvantage in that effluent treatment is needed to prevent pollution and there are further dis-advantages in connection with environmental health and with operability, etc. Furthermore, tin plate cans are often employed as food or beverage containers where the presence of chromium is not desirable.
SUMMARY OF THE INVENTION
Thus in order to overcome these disadvantages the inventors have found that it is possible to provide a film that is better than the surface treatment films of the chromic acid salt system and to form a coating which has improved corrosion resistance, oxidation resistance and paintability for DI tin cans and tin plate. The tin surface is given either a chemical or an electrolytic treatment in an aqueous solution at pH 1.0-10 which ~ 1 6 2 ~ (~ 4 P-10873 contains as its main components (1) at least one soluble compound of a metal selected from the group consisting of titanium and zirconium; (2) at least one pyrazole com~
pound of the formula:
Y - C - C - X (Where X, Y and Z are ~ independently selected Z - C N from the group consisting \ / of hydrogen atom, hydroxyl N group, alkyl group of up to H five carbon atoms, amino group, and nitro group.) (3) at least one myoinositol phosphate ester having 2-6 phosphate groups per molecule or a salt thereof and;
(4) at least one silicon compound.
DETAILED DESCRIPTION OF THE INVENTION
The titanium salts that can be used in this invention include any solu~le compound such as titanium hydrofluoride and its alkali metal salts, for example the ammonium, sodium, potassium, or lithium salts, titanyl sulphate, titanium hydroxide, and titanium oxalate; and the zirconium salts that can be used in this invention include any soluble salt such as zirconium hydrofluroide and its alkali metal salts, zirconium sulphate, zirconium hydroxide, zirconium fluoride, zirconium carbonate, and zirconium nitrate.
The total concentration of the titanium and zirconium compounds is 0.001 - lOg/l and desirably 0.01 g/l.
Examples of the pyrazole dervatives that are expressed by :he general formula:
Y - C - C - X (Where X, Y and Z are hydrogen ~ atom, hydroxyl group, alkyl Z - C N group of up to five carbon \ / atoms, amino group, and nitro N group.) H
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include 3-rnethyl-5-hydroxypyrazole, 3,5-dimethylpyrazole, 3-methyl-4-amino-5-hydroxypyrazole and 4-aminopyrazole.
The total concentration of the pyrazole derivatives is O.01-20g/1 and desirably 0.1-5g/1.
Examples of the myoinositol 2-6 phosphate esters used in this invention include myoinositol diphosphate ester, myoinositol pentaphosphate ester, and myoinositol hexa phosphate ester and the salts of the rnyoinositol 2-6 phosphate esters include the alkali metal salts and the alkaline earth metal salts and water soluble salts in which hydrogen groups of the said phosphate esters are replaced by a soluble metal such as Na, K, Li, Mg, Ca, Sr, and Ba.
Since the myoinositol hexaphosphate ester is commonly named phytic acid, this name will be used herein. Further-more, since the myoinositol di-penta phosphate esters are obtained mainly by the hydrolysis of phytic acid, phytic acid is the most useful industrially.
The overall concentration of the myoinositol 2-6 phosphate esters calculated as phosphoric acid is 0.005-50g/1 and desirably O.Ol-lOg/l.
The silicon compounds used in this invention include silicic acids such as orthosilicic acid, metasilicic acid and their alkali metal salts, silicon hydrofluoride and its alkali metal salts, ammonium silicafluoride, and colloidal silica as inorganic silicon compounds and organic silicon compounds such as the silane derivates which include alkoxy groups or acetoxy groups which are generally called silane coupling agents.
Examples include:
q _ .~
1 16~5~ P-10873 ~-amino propyltrietho~ysllane H2~'1 C3H6Si(O C2H5)3 N-3 (aminoethyl)- y -aminopropyltrimethoxysilane H2NC2H4NHC3H6si (CH3)2 N- ~(aminoethyl) - ~ -aminopropylmethyldimethoxysilane 2NC2H4NHC3H6 - s (OCH3)2 y-Glycitoxypropyltrimethoxysilane
2 / CH CH2 C3H6si (OCH3)3 Vinyltris (~-methoxyethoxy) silane CH2 = CH Si (OC2H50 CH3)3 The total concentration of the silicon compound(s) calculated as silicon is 0.001 - 10g/1 and preferably 0.005-lg/1.
One method for the preparation of the aqueous solution that is used in this invention involves dissolving the pyrazole derivative(s) in water and then dissolving the myoinositol phosphate ester. The titanium or zirconium compound(s) are then dissolved in water or in an inorganic acid such as hydrofluoric acid, sulphuric acid, or nitric acid and added to this solution. Then the silicon compound(s) are added and dissolved in this aqueous solution. In the case of the inorganic silicon compounds the compounds are first dissolved in water or an inorganic acid and then added to the aqueous solution. After dissolving all of the above mentioned components the pH is adjusted to 1.0-10. ~f the pH is less than 1.0 or more than 10.0 the etching reaction becomes severe and it is difficult to obtain a good coating.
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Inorganic acids such as hydrofluoric acid, nitric acid, sulphuric acid, phosphoric acld and condensed phosphoric acid and caustic alkalis such as sodium hydroxide, potassium hydroxide, lithium hydroxide, ammonium hydroxide, triethanol-amine, di.ethanolamine, and monoethanolamine can be used as acids and alkalis for adjusting the pH.
Oxidizing agents or reducing agents can be added as required and examples of oxidizing,agents and reducing agents that can be used include sodium nitrite, potassium nitrite, ammonium nitrite, sodium chlorate, potassium chlorate, sodium perborate, sodium bromate, potassium bromate, phosphorous acid, sodium phosphite, zinc phosphite, hypophosphorous acid, sodium hypophosphite, calcium hypophosphite, hydrazine hydrate, hydrazine sulphate, hydrazine phosphate, hydrazine hydro-chloride, and hydrazine oxalate.
The rate of coating formation is controlled by adding these oxidizing agents or reducing agents and in this way it is possible to obtain the desired coating.
The method of treatment is as follows: The tin cans or the tin plate that has been cleaned by a degreasing water wash by the usual methods is immersed for 5-10 seconds in ~he above mentioned aqueous solution that has been heated to 10-90C and a coating is formed in the same way as in the conventional treatment or alternatively the tin plate which is to be treated is made the anode and then using a carbon plate or a stainless steel plate for the other electrode the above mentioned cleaned tin can or tin plate is given an anodic electrolysis treatment or an alternating current electrolytic treatment by spacing the poles at a distance of 5-500mm and passing a current for 1 162~
-rom 0.1 seconds to 2 ~inutes at a current densi~y or O.l-iO A/dm2, desirably at 1-lOA/dm2 and then, after carrying out the electrolytic treatment, the tin can or tin plate is washed with water and dried. As required, the product may be dried without a water wash after forming the skin film by an electrolytic treatment or after simply painting with the aqueous solution of this invention by any conventional means such as spray coating, roll coating, or electrostatic coating.
The coated surface has the advantages of improve corrosion resistance, improved oxidation resistance and improved paintability and furthermore since the aqueous solutions of this invention do not contain any chromium there are considerable advantages in connection with effluent treatment, environmental health and operability.
EX~PLE 1
3-methyl-5-hydroxypyrazole (lOg) was dissolved in tap water (81) and phytic acid (5g) and 20 wt% in water of zirconium hydrofluoride (25g) were then dissolved successively in this solution. Then, 5g of y-aminopropyltriethoxysilane and 2g of 55% hydrofluoric acid were added and dissolved and then, after the addition of 2g of 30% aqueous hydrogen peroxide the total volume was made up to 101 by adding tap water. The pH of this aqueous solution was 2.7.
After cleaning a tin plate can by degreasing with a solution of 10 g/l of a conventional alkaline degreasing agent and rinsing with water, a coating was formed by spraying the surface for 30 seconds at 1.0 kg/cm2 (gauge pressure) with the above mentioned aqueous solution heated to 45C after which the residual aqueous solution was removed ~y first rinsing with tap water for 20 seconds 1 1 6 2 .~
and then by spraying with deionised water with a specific resistance in excess of 500,000 ohm.cm the can was dried for 3 minutes in a hot air convection oven at 200C.
For a paintability test, an epoxy based inner surface paint "CanCoat" (trademark , Kannishi Paint) for use on tin was painted on part of the treated surface so as to give a dry paint film thickness of about 5/~ and the can was heated for 4 minutes in a hot air convection oven at 22C.
The results of testing the treated can, with and without painting are shown in Table 1.
3-methyl-5-hydroxypyrazole (12 g) was dissolved in tap water ( 5 1 ) and then phytic acid (10 g) was added to make up solution A. Potassium fluotitanate (10 g) and
4~/O silicon tetrafluoride (20 g) were then dissolved in 41 of tap water to make up solution B. Then after mixing solutions A and B and adding and dissolving sodiurn nitrate (10 g) the total volume was made up to 101 with tap water.
The pH was adjusted to 9.0 using aqueous arnmonia to yield the aqueous solution.
A coating was then formed on a tin can that had been cleaned using the same method as in Example 1 by spraying for 20 seconds at 0.8 kg/cm (gauge pressure) with the above-mentioned aqueous solution that had been heated to 40C and the residual aqueous solution was then removed by first rinsing for 10 seconds in tap water and then 10 seconds in deionized water (resistance in excess of 300,000 ohrn.cm) followed by drying in a hot air convection oven at 150C.
The can was painted in the same way as in Example 1. The results of testing are shown in Table 1.
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~y~PLE 3 After cleaning a tin can in the same way as in Example 1, the can was immersed for 10 seconds in the same aqueous solution as used in Example l and dried ror 3 minutes after removal from the aqueous solution in a hot air convection oven at 120C without first rinsing with water.
The can was painted in the same way as in Example l. The results of testing are shown in Table l.
~OMPARATIVE EXAMPLE 1 For purposes of comparing Examples l to 3 with chromic acid based treatments, after cleaning a tin can in the same way as in Example l, except the treatment was as follows:
Compositlon of the Aqueous Solution:
Anhydrous chromic acid 40g) made up to 101 Phosphoric acid (75%) 20g) with water Aqueous Solution Temperature 30 C
Treatment Conditions:
Spray treatment (spray pressure: 0.5kg/cm gauge pressure) Spray time 30 secs.
Results of testing are shown in Table l.
An aqueous solution was made by the method outlined in Example l but the zirconium hydrofluoride was omitted and the pH was adjusted to 3 with hydrofluoric acid. A can was processed as in Example l and the results of testing are shown in Table 1.
An aqueous solution was made by the method outlined in Example l but the phytic acid was omitted and the pH was adjusted to 3 using aqueous ammonia. A can was processed as in Example l and the results of testing are shown in Table l.
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_Oi~ARATIVE ~A.`~LE 4 An aqueous solution was made by the method outlined in Example l but the y-aminopropyltriethoxysilane was omitted and the pH of thls aqueous solution was adjusted to 3 with aqueous ammonia. A can was processed as in ~xample l and the results of testing are shown in Table l.
EXPERIMENTAL RESULTS
Example Number Treated Only Can Painted Can Corrosion Moisture Adhesion of Resistance Resistance Paint Film l 5 points 5 points 5 points Comparative l 4.5 5 5 Comparative 2 l l 4 Comparative 3 l l 3 Comparative 4 2 l 4 Test Methods for Table l Corrosion Resistance Test The tin can specimen was placed base up and introduced into a salt water spray tester and after testing for 30 minutes as prescribed in JIS-Z-2371 the tarnlshed condition of the surface of the tin can was assessed. The scale of assessment was as follows: No tarnishing 5 points, tarnishing over the whole surface l point with intermediate scores for intermediate states of tarnishing.
Moisture Resistance Test The tin can specimen was placed base up and introduced into a moisture tester in accordance with JIS-Z-0228, the state of tarnishing of the surface of the tin can was assessed after a three hour test. The assessment was made on the same basis as the corrosion resistance test.
Test of the Adhesion of the Paint Film After immersing the painted can for 30 minutes in a 1% aqueous solution of citric acid it was washed with water and dried. Then, after making an X shaped cut in the paint surface on the outer surface of the specimen through to the underlying metal with a sharp blade, CELLOPHANE (trade mark) adhesive tape was applied and the extent of paint removal when the tape was pulled off was assessed. Evaluation was made on the following basis: No separation of the paint film at all - S points, paint film almost completely removed - 1 point and intermediate scores for conditions of removal intermediate these two extremes.
3 methyl-5-hydroxypyrazole (5 g) and 3,5-dimethyl-pyrazole (5 g) were dissolved in tap water (8 1) and then phytic acid (10 g), 40% titanium hydrofluoride (10 g), 20% zirconium hydrofluoride (10 g) and acidified ammonium fluoride (5 g) were added successively and dissolved and then ~-aminopropyl-triethoxysilane (10 g) was dissolved in this solution. After making up to a total volume of 10 1 with tap water, the pH was adjusted to 4 with aqueous ammonia.
After cleaning a ~ 50 tin plate panel (0.3 x 70 x 150mm) using the same method as in Example 1 it was treated using the above mentioned aqueous solution under the conditions noted below, rinsed with water and dried.
The results of testing are shown in Table 2.
Treatment Conditions Aqueous solution temperature 50C
Type of electrolysis Direc~ current electrolysis Current density 3A/dm Time for which the current 5 seconds was passed Pole ratio 1:1 Distance between poles 50mm Anode Tin plate specimen Cathode Car~on sheet .~ ~
~ 1~250~ P-~.0873 ).~PA~.TIV _E~ PLE 5 Eor comparison Wl h Example 4 using conventional chromic acid salt based -xea.men.s a sheet of "50 tin plate (0.3 ,~ 70 x 150mm) was cleaned with the same method as used in Example 1 and then given an electrolytic treatment in accordance with the conditions of treatment noted for Example 4 using the aqueous solution of Comparative Example 1 rinsed with water and dried.
The results o~ testing are shown in Table 2.
EX~PLE 5 After dissolving 3-methyl-5-hydroxypyrazole (10 g) in distilled wa.er (8 1), phytic acid (10 g) 40~ titanium hydrofluoride (1 g) and acid ammonium fluoride (10 g) were added successively and dissolved and then y-amino-propyltriethoxysilane (5 g) was added and dissolved.
The total volume was made up to 101 with distilled water and the pH was adjusted to 8.5 with aqueous ammonia.
After cleaning a ~50 tin plate panel (0.3 x 70 x 150mm) by the same method as that used in Example 1 and immersing it for 5 seconds in the above solution which had been heated to 30C, the excess aqueous solution was removed in such a way as to leave an aqueous solution coating of 5ml/m using neoprene rubber rollers and then the panel was dried in a hot air convection oven at 150C.
The results of testing are shown in Table 2.
COMPARATIVE E~PLE 6 An aqueous solution was made up as in Example 5 but the phytic acid was omitted and the pH was adjusted to pH 8.5 with aqueous ammonia and a panel treated as in Example 5.
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Corrosisn ~idation Example Number Resistance esistance Paintabilitv 4 5 points 5 points 5 points Comparative 5 5 5 5 Comparative 6 2 3 4 Test Methods for Table 2 Corrosion Resistance Te_ Specimens were placed in a salt water spray tester and after testing for 24 hours according to JIS-Z-2371 the state of tarnishing was assessed. The evaluation was made as follows: No tarnishing developed - 5 points, tarnish developed over the whole surface - 1 point, states of tarnishing between these extremes, intermediate scores.
Oxidation Resistance Test After heating a specimen for 30 minutes in an electric oven (air atmosphere) at 210C the extent of yellowing was assessed visually. The evaluation was made as follows:
No color change at all - 5 points, color change to a strong yellow color - 1 point, color changes between these extremes -intermediate scores.
Paintability Test Five ml of an epoxy based can paint sold under the trade mark "Can Coat" by Kannishi Paint was dripped by pipette onto the surface of a specimen that was held horizontally and the way in which the paint spread out was assessed.
The valuation was made as follows- Paint spread out and did not leave droplets - 5 points, the paint remained in the form of the droplets - 1 point, intermediate extent of spreading out - intermediate scores.
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